DESCRIPTION OF THE PREFERRED EMBODIMENTS

Referring first to FIG. 1, the conventional hardware and software for converting characters from a printed form into stored digital data comprises a scanner, such as any 300 pixel bi-level scanner, and a central processing unit (CPU). The CPU is connected to conventional peripheral devices such as a display, a data storage (e.g. a hard disk file) and a printer. The scanner converts the printed image from the form into bi-level digital data which is transferred to the CPU and converted into an array of 0's and 1's, representing white and black pixels on the scanned form. Conventional OCR software is then utilized to recognize characters from the array of digital data. The CPU then stores and/or displays the results of the OCR software operation to any of its peripheral devices. Thus, the output from operation of the OCR software is character data, represented for example in ASCII format, which can be easily manipulated by the CPU and stored or transmitted to peripheral devices.

As illustrated in FIG. 1, in the present invention a blank master form is first scanned, converted to bi-level data, received by the CPU and stored. An example of a master form is shown in FIG. 12. A completed or filled in form, is then scanned, converted to bi-level data and stored by the CPU in an array referred to as an "old-map". An example of a filled-in or data form is shown in FIG. 13. The present invention is the method of data extraction performed by the data extraction software which allows just the pixels in the data regions or fields to be extracted from the old-map so that this data can then be received and operated on by the OCR software in the conventional manner. The functions of the data extraction software will be described with reference to the schematics of FIGS. 2-5 and to the "pseudo-code" included in Appendix A, which is incorporated herein by reference. A list of definitions to assist in understanding the pseudo-code is listed in Appendix B and incorporated herein by reference.

Referring now to FIG. 2, the data extraction software includes two phases, referred to as Phase I and Phase II. The operation of Phase I is identical for both the master form and the data form, while Phase II operates only on the data form. Thus, the first step in the data extraction process is the scanning of the blank master form and, through the use of the functions in Phase I to be described below, the creation of a master-form-description. The master-form-description includes the identification of all lines by location and length and the skew of the form, i.e. its angular orientation relative to a fixed coordinate system of the scanning device.

Referring to FIG. 3, the description of the operation of Phase I will be described relative to its operation on a scanned data form, i.e. the old-map, although as just indicated, the operation of Phase I is identical for the blank master form. This is because the function of Phase I is to locate all horizontal lines on the form, to generate a line-list and to identify the location and length of all of the lines on the form, be it the master form or the data form.

The old-map is a two-dimensional array of digital data corresponding to the pixels of the scanned data form image. Each pixel is either 1 or 0, or "ON" or "OFF", depending upon the presence or absence of either background lines or character data at the corresponding X-Y location. This digital data is analyzed with a Build Table routine (Appendix A, 1.1), which is a search for vertical runs of ON bits having a height less than an predetermined number, e.g. 3 in the preferred embodiment. The Build Table routine identifies all such vertical runs and creates a cluster-list for identifying the location of these vertical runs. The Build Table routine outputs a list of all vertical clusters located in the old-map and a cluster-index which points to the start of each row for each 3-pixel-high vertical cluster. This information is then passed to the Build Lines routine (Appendix A, 1.2) whose function is to connect horizontally related clusters to detect horizontal lines. Thus, the Build Lines routine searches through all clusters in the cluster-list, and with knowledge of their location from the cluster-index, identifies horizontal lines. If there is an additional cluster within a predetermined minimum length away from the portion of the line just built, then that cluster is added to the existing line. The output of the Build Lines routine is a line-list of all of the lines in the data form. Each line in the line-list is identified by its row-start, row-end, column-start, and column-end.

The lines are then normalized or de-skewed by the Normalize Lines (Appendix A, 1.3) routine. Because the data form may not have been perfectly aligned with the scanning device, or the background lines on the form not perfectly oriented on the form, the lines which have been identified from the Build Lines routine may be skewed. This means that the pixels comprising a line may not necessarily begin and end on the same row. The Normalize Lines routine calculates the average skew of the lines in the line-list. The skew is defined as the ratio of the difference between the start and stop row of a line to the difference between the start and stop column of the line. After the skew has been calculated in this manner, the lines are normalized or de-skewed so that each line in the line-list can now be identified by a row-start, column-start and column-end. As a necessary output of the Normalize Lines routine, the skew of the data form has been calculated and is available for later use. The Connect Lines routine (Appendix A, 1.4) then takes the list of Normalize Lines and determines if any of these lines are within a predetermined line tolerance of one another. If so, the lines are connected to make a single line, thereby reducing the number of lines in the line-list. As a result of the Connect Lines routine, the output is a data-form-description which is a listing of all horizontal lines in the data form, where each of those lines is identified by its row-start, its column-start and its column-end. A similar procedure may be performed to detect and identify vertical lines. Thus, at the completion of Phase I the data extraction software has generated in digital form an exact replica of all background lines present on the filled-in data form.

As previously described, the Phase I process is first performed on a master form, i.e. a form identical to a filled-in data form, but without any character data present in the data fields. This is the first step in the process in the present invention and results in a master-form-description which is a list of all horizontal lines on the master form identified by row-start, column-start, and column-end. Vertical lines would be identified by row-start, column-start, and row-end.

Referring now to Paragraph 1.5 of Appendix A, the next step is the creation of the data-field-masks from the master form, utilizing the master-form-description output by Phase I when the master form was scanned. The function of the Create Masks step is to define a series of rectangular masks separated by portions of the lines identified in the line-list of the master form, wherein each mask corresponds to a desired region where a data value is located in the data form. While there are numerous techniques for creating the masks, the preferred technique is to generate the output of Phase I from the master form on a visual display (See FIG. 1). A user, through the use of a light pen, then points to those regions bounded by lines where it is desired to extract data from the data forms. For example, the light pen could identify the upper left and the lower right corners of each desired data mask, which would result in identifying the location and dimensions of each rectangular data region. Each data mask has a perimeter which is preferably spaced from the lines by a predetermined data margin, D. As a result of the Create Mask step, the CPU will have stored the location and dimensions of the data regions by use of a mask-list, which identifies each mask by row-start, column-start and row-end, column-end. Since the normalized lines in the master form are presented on the visual display during this step it is not necessary to compensate for skew when the data masks are created on the master form.

At this point in the description of the invention, a master form has been scanned, a master-form-description has been defined through the use of Phase I (FIG. 3 and Appendix A, 1.1-1.4), the data masks have been created, a data form has been scanned and a data-form-description has been generated through the use of Phase I.

Phase II is now performed on the data form. Referring now to FIG. 4 and Paragraph 2 of Appendix A, it is noted that Phase II has several functions. The first function is the Prepare Form routine (Appendix A, 2.1) which compares the data-form-description with the master-form-description in order to calculate the differences in terms of field locations between the two descriptions. The function of the Prepare Form routine can be better understood by reference to FIG. 6. Because the data form cannot always be perfectly aligned with the scanner, there will usually be both vertical and horizontal offsets of the data form lines from the master form lines form each time a new data form is scanned. Thus, the Prepare Form routine compares each line in the line-list in the master-form-description with its corresponding line in the line-list in the data-form-description, and using the differences between the row-start, column-start and column-end values, determines the offset of the data form from the master form. This offset is essentially the horizontal adjustment (horiz-adj) and the vertical adjustment (vert-adj) necessary to transform the master form into the data form. The output of the Prepare Form routine are the values or horiz-adj, vert-adj, and skew, the latter term being the rotation of the data form relative to the master form (See FIG. 6).

In the Get Data Masks function (FIG. 4 and Appendix A, 2.2), the data masks created from the master form and which are identified by location and dimension, are retrieved and placed in corresponding locations on the data form so as to create data masks located in the data form. As part of the Get Data Masks function, the width of the output array is calculated as the width of the longest data mask created from the master form plus a constant (such as two bytes). This number becomes the width of the output image containing the extracted data.

The next function in Phase II is the Read Group function (Appendix A, 2.3), which transfers the old-map image from data storage into main memory, creating an array of records, referred to as "current-group", where each record has a width corresponding to the width of the scanned image. Thus, the Read Group function essentially converts the bi-level raw data into an array having a width and height corresponding to that of the scanned image. The output of the Read Group function is the current-group.

The Copy Masks function of Phase II comprises the five routines shown in FIG. 5. The Copy Masks function locates the data masks in a current-group to be extracted, grows or enlarges the masks, if necessary, to capture information which lies outside of the masks, removes any lines which intrude into the data masks, and finally writes the extracted data to the extracted image. As part of the Copy Masks function, the mask parameters are calculated in the Calculate Mask Parameters routine. This process essentially adjusts the data masks to compensate for skew, horizontal offset and vertical offset relative to the master form. The operation of the Calculate Mask Parameters can best illustrated by reference to FIG. 6. The input to the routine are the data mask locations and dimension, and vert-adj, horiz-adj and skew which have been previously calculated in the Prepare Form function. FIG. 6 illustrates how each of these parameters is used to transpose the location of the data masks, whose relationships relative to the master form are known, to their correct locations on the data form. As shown in FIG. 6, the skew rotates the masks by the degree of the skew. However, while this may be an optimal solution in that the size of the masks remain the same as in the master form, the CPU cost in performing the rotation step and in growing the masks may be inefficient if the skew remains within a reasonable range. In an alternative technique, as shown in FIG. 7, the skew is used to alter the height of the mask in the data form, so that the resulting mask in the data form retains its rectangular shape. As the skew increases, the chance of the predefined rectangle not fitting inside the field increases. To compensate for this, as the skew becomes greater the heights of the masks are reduced. The output of the Calculate Mask Parameters routine is the location and dimension of the data masks within the data form, each data mask being defined by its start or left column, its end or right column, and its top-row and bottom-row.

After the Calculate Masks Parameters routine has been performed, if the data is perfectly located within the masks, then no additional data extraction routines are needed and the data can be extracted directly by the Write Row routine (Appendix A, 2.4.5). Perfect data is considered to be data that resides entirely within a predefined data mask. If there are no ON pixels along the parameter of the mask, the data is considered to be wholly inside the mask and completely perfect. In the Write Row function, all of the data in the current-group which is contained in the rectangles defined by left, right, top-row and bottom-row, i.e. all of the data in the masks, is copied to a new file. The result is that the new file contains only extracted data without any extraneous lines of the background form. The data located in the new file can then be operated on by conventional OCR software to identify the data as specific character data. In addition, because each data mask is predefined as corresponding to a certain significance, i.e. name, age, etc., the data which has been extracted from the form and converted to character data by the OCR software is immediately identifiable with a predetermined significance.

If, on the other hand, the data present in the data masks is not perfectly located within the perimeter of the data masks, then it is necessary to perform one of the additional functions of the Copy Masks function (FIG. 5).

The Remove Vert Bars (Appendix A, 2.4.2) removes vertically oriented bars which may be intruding into a data field, such as the portion of the signature in the "Middle" data field shown in FIG. 13. The Remove Vert Bars routine checks the two right-most and left-most bytes for the entire height of each field to determine if there is a run of connected ON bits that occurs that forms a vertical line. If such a line is not included since it assumed that data occurring beyond the vertical bar belongs to another field.

Referring now to FIG. 8, the Grow Bottom routine (Appendix A, 2.4.4) enlarges the bottom of the mask until all of the data in the field has been captured or until the growth of the mask reaches a predetermined limit, defined as 2D, the spacing between neighboring data masks. The mask is grown and during the growth lines are detected in the manner similar to the line detection technique described in Phase I. The mask is grown by searching a perimeter row for ON bits. If a violation (the presence of ON bits) is encountered, the column to the left and right of the violation on the next row (one row up if growing the top of the mask, one row down if growing the bottom of the mask) is checked for ON bits. If either column has ON bits, then the process is repeated. This process terminates if either both bytes become OFF, or the maximum growth limit of 2D is reached. Once any portion of a line is detected during mask growth the complete line is removed. A similar technique is used in the Grow Top (Appendix A, 2.4.3) to enlarge the bottom of the mask to capture data. For example, the word "Twin" in FIG. 13 would be located entirely within the grown data mask and the line removed. The line removal process is activated whenever the Grow Top or Grow Bottom routine detects a line in the ambiguous 2D area (FIG. 8). Line removal begins by following the path of the line and erasing the line as it is followed. The erasing of the line also erases anything that lies either one pixel above or one pixel below the line. This is to account for edge noise that is generated during printing and scanning. As the line is being erased, a check is made to determine whether there is any data that may be either touching or going through the line. If such data is found, the areas where the pixels may be from the line or from the data are not erased (see FIG. 9). The line detection and erasing algorithm has also been implemented in APL and is listed in Appendix C together with descriptions of the respective lines and routines. FIGS. 10 and 11 illustrate a pattern processed by the algorithm of Appendix C wherein FIG. 10 is the input pattern where all black or ON pixels are denoted with an asterisk, and FIG. 11 is the result of the line detection algorithm wherein the lines have been detected and the asterisks replaced with dashes.

While the preferred embodiments of the present invention have been illustrated in detail, it should be apparent that modifications and adaptations to those embodiments may occur to one skilled in the art without departing from the scope of the present invention as set forth in the following claims. ##SPC1## ##SPC2## ##SPC3##

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic illustrating the relationship of the invention to conventional hardware and software for scanning an image and converting the image to stored characters through the use of OCR software;

FIG. 2 is a schematic illustrating the two portions of the data extraction software designated Phase I and Phase II ;

FIG. 3 is a schematic of the functions present in the Phase I portion of the data extraction software;

FIG. 4 is a schematic of the functions present in the Phase II portion of the data extraction software;

FIG. 5 is a schematic of the Copy Masks function of the Phase II portion of the data extraction software;

FIG. 6 is an illustration of the manner in which horizontal and vertical adjustments between the master form and the data form are used to register the data form following scanning;

FIG. 7 is a depiction of an alternative solution to the problem of skew in the location of a data mask;

FIG. 8 is a graphical illustration of the Grow Bottom function for growing a data mask to capture data which crosses a mask perimeter;

FIG. 9 is a graphical depiction of a line removal process to capture character data which is intersected by a line, the line having been detected during the Grow Bottom function;

FIG. 10 is a representation of ON pixels for data intersected by a line;

FIG. 11 is a representation of the ON pixels depicted as dashes following detection of the line pixels through the use of the algorithm in Appendix C;

FIG. 12 is a typical bland birth certificate master form; and

FIG. 13 is a typical filled-in birth certificate data form.

TECHNICAL FIELD

This invention relates to optical character recognition (OCR) devices and processes, and more particularly to a computer-implemented method for automatic extraction of data from printed forms.

BACKGROUND OF THE INVENTION

Automatic computer-implemented reading of data from printed forms is typically done in a sequence of three steps. First a form is optically scanned to create an electronic image, which is then written in digital storage as a rectangular array of 0's and 1's representing white and black subareas or pixels. Then the image is processed to extract regions or fields containing the data to be read. Finally, the black and white subimage in each extracted region is interpreted and expressed as an alphanumeric code, such as ASCII or EBCDIC.

The data present in printed forms may be defined as having two aspects: a value and a significance. For example, the word "Yes" is a value that becomes data only when its significance, i.e., the question it answers, is made clear. Printed forms provide a conventional means for recording data in which significance is predefined as a background of text and graphics, such as boxed areas. Since forms are printed mechanically, the background is identical over different instances of the same form. Thus the position of data values on the form is in correspondence with the data significance. Optical character recognition (OCR) devices take advantage of this fact to read data from credit card receipts, billing statements, etc. Such "OCR forms" are designed with data values entered in spaces well separated from background printing to assure that the latter are not erroneously interpreted as data values. Data significance does not appear explicitly, but is stored in the computer and associated with the data values on the basis of position in the image. In some cases, forms are printed in a color invisible to the scanner to avoid a possibility of confusion. Data values are carefully positioned during printing, and the form precisely registered during scanning. All these steps serve to guarantee that the data values are exactly where the reading or scanning equipment performs its extraction process.

In recent years, demand has grown for a capability to capture data from printed forms that do not meet OCR constraints. Forms routinely used in government and commercial operations, such as birth and marriage certificates, are designed to be intelligible to the human eye and brain. While people are sophisticated processors of visual images, they also require that both attributes of a data element, the significance and the value, be present on the document. Thus background printing is provided to supply the meaning of each data field, and lines and boxes are imposed to make clear the association of data value and data significance. The crowded appearance of these "people forms", compared with OCR forms, is a necessary outcome of a requirement to pack a great deal of information into a limited space.

It is likewise difficult to enforce controls in the preparation of people forms. A birth or marriage certificate filled out with a typewriter is registered by eye, often with errors in translation and skew compared to the ideal orientation. Data values may superimpose on the form background as a result. The printing process itself is subject to mechanical slippage that may give the same effect. Finally, mechanical slippage and electronic noise occurring during the optical scanning process present a further source of registration error. This is particularly true if economical general-purpose scanners are used. The net result of all these factors is that printing of a given data value on people forms may be skewed, may overlap boundary lines separating data regions, and even when ideally positioned does not consistently appear in a fixed, predictable region in scanned images of different instances of the form. These difficulties pose severe problems for automatic computer-implemented data extraction, rendering inapplicable the sort of processing used for OCR forms.

SUMMARY OF THE INVENTION

The invention is a computer-implemented method operable with conventional OCR scanning equipment and software for the automatic extraction of data from printed forms.

A blank master form is scanned and its digital image stored. Clusters of ON bits of the master form image are first recognized as part of a line and then connected to form lines. All of the lines in the master form image are then identified by row and column start position and column end position, thereby creating a master-form-description. The resulting image, which consists only of lines in the master form, can then be displayed. Regions or masks in the displayed image of master form lines are then created, each mask corresponding to a field where data would be located in a filled-in form. Each data mask is spaced from nearby lines by a predetermined data margin, referred to as D.

A filled-in or data form is then scanned and lines are also recognized and identified in a similar manner to create a data-form-description. The data-form-description is compared with the master-form-description by computing the horizontal and vertical offsets and skew of the two forms relative to one another. The created data masks, whose orientation with respect to the master form has been previously determined, are then transposed into the data form image using the computed values of horizontal and vertical offsets and skew. In this manner, the data masks are correctly located on the data form so that the actual data values in the data form reside within the corresponding data masks. Routines are then implemented for detecting extraneous data intruding into the data masks and for growing the masks, i.e. enlarging the masks to capture data which may extend beyond the perimeter of the masks. Thus, the data masks are adaptive in that they are grown if data does not lie entirely within the perimeter of the masks. During the mask growth routine, lines which are part of the background form are detected and removed by line removal algorithms.

Following the removal of extraneous data from the masks, the growth of the masks to capture data, and any subsequent line removal, the remaining data from the masks is extracted and transferred to a new file. The new file then contains only data comprising characters of the data values in the desired regions, which can then be operated on by conventional OCR software to identify the specific character values.

For a fuller understanding of the nature and advantages of the present invention reference should be made to the following detailed description taken in conjunction with the accompanying drawings.